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SThe Subaru EJ201 and EJ202 were 2. Like its EJ20 predecessor, the Subaru EJ201 and EJ202 engines had an aluminium alloy block with 92. 0 mm stroke for a capacity of 1994 cc. The cylinder block for the EJ201 and EJ202 engines had an open-deck design whereby the cylinder walls were supported at the three and nine cómo se hace el pan de banana’clock positions.

The crankcase for the EJ201 and EJ202 engines had five main bearings and the flywheel housing was cast with the crankcase for increased rigidity. While the pistons for the EJ201 and EJ202 engines continued to be produced from cast aluminium, the pistons were lighter than those in its EJ20 predecessor. To reduce friction, the pistons for the EJ201 and EJ202 engines had reduced piston pin offset and a molybdenum coating. Other features of the pistons included solid-type piston skirts, flat top combustion surfaces and reduced top land to cylinder clearance. The air intake system for the EJ201 and EJ202 engines was tuned to achieve high torque in the low to medium engine speed range. For lower intake air temperature, the air inlet duct received air from outside the under bonnet area. The EJ201 and EJ202 engines had an aluminium alloy cylinder head with cross-flow cooling.

Due to the cylinder head offset, the left camshaft was longer than the right camshaft to align the cam belt sprockets. Both camshafts were driven by a single belt which had round profile teeth for quiet operation and was constructed of wear-resistant double canvas and heat resistant rubber materials with a wire core. The EJ201 and EJ202 engines had four valves per cylinder that were actuated by roller rocker arms. The EJ201 and EJ202 engines had multi-point sequential fuel injection and centrally located spark plugs. The EJ201 and EJ202 engines had a compression ratio of 10. EJ201 and EJ202 engines less susceptible to detonation or pinging, enabling a higher compression ratio. For the EJ201 and EJ202 engines, the injection and firing order was 1-3-2-4.

A new 4-2-1 exhaust system with equal length header pipes. Reviews is an independent publisher of car reviews, recalls, faults, image galleries, brochures, specifications and videos. The FB engines were manufactured at Subaru’s Gunma Oizumi factory which was developed exclusively for the production of the FB engine. The FB25 engine had an open-deck, aluminium alloy block with 94. 0 mm bores and a 90. FB25 engine had cast iron liners. Due to its revised connecting rods and valvetrain components, the FB25 block was the same size as its EJ253 predecessor, despite its smaller bore and longer stroke.

According to Subaru, the longer stroke improved fuel efficiency by enabling faster air induction and reduced unburnt fuel during cold starts. The FB25 engine had separate cooling circuits for the cylinder block and head to improve coolant distribution. Around the block, the flow rate was limited to maintain a high temperature for the cylinder liner oil, thereby reducing friction from the motion of the pistons. To reduce engine width and enable its longer stroke, the FB25 engine had asymmetrical, diagonally-split connecting rods. Compared to the EJ253, the FB25 engine achieved a 28 per cent reduction in frictional losses due to its lighter connecting rods, lighter pistons and wrist pins, and lower piston-ring tension. Furthermore, the size and shape of the resonators in the intake manifold were streamlined.

The FB25 engine had an aluminium alloy cylinder head with separately cast camshaft carriers so that cores in the cylinder head could be omitted for a reduction in metal thickness. As noted above, cylinder head cooling was enhanced by using separate circuits for the cylinder block and head. The FB25 engine had double overhead camshafts that were driven by a maintenance-free chain. For the FB25 engine, a chain drive was adopted because it enabled a narrower included valve angle and a reduction in the sprocket diameters of the crank and camshaft for reduced width. Whereas the fuel injectors for the EJ253 engine were in the intake manifold, the fuel injectors for the FB25 engine were moved to the cylinder head. According to Subaru, positioning the injectors in the cylinder head enhanced the flow of atomised fuel, thereby improving fuel efficiency and reducing exhaust gas emissions. The FB25 engine had coil-on-plug ignition with an integrated igniter for each cylinder.

The spark plug caps, which provided contact to the spark plugs, were integrated with the ignition coil assembly. For the FB25 engine, cooling around the spark plugs was improved for a higher knock limit, increased power and improved fuel efficiency. For the FB25 engine, the diameters and lengths of the exhaust manifold were modified to improve catalytic converter warm-up and increase power output. Furthermore, the more free-flowing exhaust system contributed to higher power output.

By using EGR, combustion temperatures were reduced such that the engine was less susceptible to knock and injection timing could be advanced. New pistons with raised crown surfaces for a higher compression ratio of 10. The exhaust manifold collector had a smaller surface area to reduce mass and increase the high temperature performance of the catalytic converter. Reviews is an independent publisher of car reviews, recalls, faults, image galleries, brochures, specifications and videos.

UCT is taking the threat of infection in our university community extremely seriously and has created a Coronavirus Disease 2019 updates page which offers a range of relevant information. The Faculty of Health Sciences puts the safety of staff and students at the forefront of its response to the pandemic. New guidelines and processes are being developed for adapted ways of teaching, learning, research and working in health services. The Institute has curated a go-to range of reliable information to guide and assist staff and students during this time of crisis. We are continuously updating the various COVID-19 resources listed below.

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